pressure broadening effects of inert gases on co2 and ch4 ......broadening of n2 shows negative...
TRANSCRIPT
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Pressure broadening effects of inert gases on CO2 and CH4 measurement using a wave scan-cavity ring down spectrometer
H. Nara, H. Tanimoto, Y. Nojiri, H. Mukai, K. Katsumata, Y. Tohjima, T. Machida
National Institute for Environmental Studies 16-2 Onogawa, Tsukuba, Ibaraki 305-8506, Japan
A wavelength-scanned cavity ring-down spectrometer (CRDS, available from PICARRO, Inc., Santa Clara, CA) is a rapidly spreading observation instrument which can detect atmospheric CO2, CH4, and H2O simultaneously based on the principle of laser absorption technique (Crosson, 2008). Chen et al. (2010) made airborne observations of CO2 and CH4 over the Amazonian rain forest using a CRDS and evaluated its performance for CO2 measurement in comparison to NDIR. These investigators reported that CO2 mixing ratios from both CRDS and NDIR instruments showed good agreement, except that the CRDS measurements were affected by the variations in inert gaseous species (N2, O2, and Ar) due to pressure broadening effects on absorption spectrum of CO2 and CH4. However, the magnitudes of the pressure broadening effects were not tested. In this work we have evaluated the pressure broadening effects through laboratory experiments. Figure 1 shows pressure broadening effects of the inert gases on the measurement of CO2 and CH4, expressed as a function of inert gas mixing ratio added. The pressure broadening of N2 shows negative effect on CO2 and CH4 while the effects of O2 and Ar are positive, suggesting the largest impact of N2. Take into account that the typical analytical precision of the CRDS is ±0.03 ppm for CO2 and ±0.3 ppb for CH4, we found that pressure broadening effects are not negligible when the N2 increases more than 0.1% for CO2 and 0.9% for CH4 from the original mixing ratio. These results imply possible biases in atmospheric CO2 and CH4 measurements using the CRDS when synthetic gas standards are used as a reference gas.
References:
E. R. Crosson. A cavity ring-down analyzer for measuring atmospheric levels of methane, carbon dioxide, and water vapour. Appl. Phys. B92, 403-408, 2008
H. Chen; J. Winderlich; C. Gerbig; A. Hoefer; C. W. Rella; E. R. Crosson; A. D. Van Pelt; J. Steinbach; O. Kolle; V. Beck; B. C. Daube; E. W. Gottlieb; V. Y. Chow; G. W. Santoni; S. C. Wofsy. High-accuracy continuous airborne measurements of greenhouse gases (CO2 and CH4) using the cavity ring-down spectroscopy (CRDS) technique. Atmos. Meas. Tech., 3, 375-386, 2010
Figure 1. An example of estimated CRDS (model G1301) responses of CO2 (top) and CH4 (bottom) against N2 (solid line), O2 (dashed line), and Ar (dotted dashed line) added in the compressed natural air.
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0 0.2 0.4 0.6 0.8 1Pressure broadening effect on
CO2(ppm
)
N2
O2
Ar
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0
0.1
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0 0.2 0.4 0.6 0.8 1Pressure broadening effect on
CH4(ppb)
Added gas increase (%)
N2
O2
Ar
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A Multi-Year Record of Airborne Continuous CO2 in the U.S. Southern Great Plains
Sébastien C. Biraud1, William J. Riley1, Margaret S. Torn1, James R. Smith2
1 Earth Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 2 Atmospheric Observing Systems, Inc., Boulder, Colorado
We report on three years of airborne measurements of continuous atmospheric CO2 concentrations over the Atmospheric Radiation Measurement Program (ARM) Climate Research Facility (ACRF) in the U.S. Southern Great Plains. These continuous measurements are collected weekly from a small aircraft (Cessna 206) on a series of horizontal legs ranging from 17,500 feet down to 1,500 feet above sea level. The continuous CO2 observations are measured using a CO2 analyzer built by Atmospheric Observing System Inc., based in Boulder, Colorado. The analyzer has non-imaging optics and negligible sensitivity to motion of platform. The NDIR Analyzer is the core element of the system. Accuracy, including bias, is approximately 0.1 ppm of CO2 DMF at 1 Hz. Each flight lasts between 2.5 and 3 hours, yielding about 10,000 CO2 measurements per flight. Since November 2007, more than 300 continuous CO2 vertical profiles have been collected, along with NOAA/ESRL 12-flask (carbon cycle gases and isotopes) packages for validation. Comparison between the continuous and flask CO2 measurements indicates a no systematic difference. .
Figure 1. Weekly average continuous CO2 concentrations collected in the U.S. Southern Great Plains since Jan. 2008.
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Detection of combusted methane emissions for the city of Bern (Switzerland) by
analysis of high-resolution O2 and CO2 observations.
S. van der Laan, I.T. van der Laan-Luijkx, M. Haeberli, M. Leuenberger
University of Bern, Physics Institute, Climate and Environmental Physics, Sidlerstrasse 5, CH-3012 Bern,
Switzerland
Anthropogenic CO2 emissions are widely considered to be the main cause of enhanced global
warming since the 18th
century1. Although the CO2 fluxes on the global scale are relatively well
understood, little is still known about the spatial and temporal variation in CO2 fluxes on regional to
local scales.
This project aims at quantifying one of the largest contributors of CO2 emissions in the city of Bern,
Switzerland: combusted methane. Natural gas accounts for more then 20% of the annual energy
consumption as it is used for heating and cooking purposes by the approx. 124.000 inhabitants.
Since the year 2007 the University of Bern measures semi-continuously ambient CO2 and O2
concentrations at the roof of the university building in the centre of Bern. A clear diurnal pattern is
observed with rapid increases in the CO2 concentration from the background concentration and
concurrent decreases in the O2 concentration. These so-called events typically last for about 8-12
hours and are caused by a combination of regional CO2 sources and changes in atmospheric
stability (i.e. lack of turbulence). Often, these events have smaller events superimposed on them
with a typical duration in the order of 2-4 hours, representing local CO2 sources. The events are
selected with an automated FFT-filter. A regression plot is made for each event between CO2 and
the concurrent O2 to determine the stochiometric ratio2,3
. A stochiometric ratio of -2 mol O2/mol
CO2 indicates combusted methane. To determine the surface fluxes for these events we use the 222
Rn-tracer method4,5,6
. Accompanying measurements of 13
CO2 are used to determine the δ13
C
signature of the local natural gas mix. At the meeting we will show our first results and outline our
future perspectives.
References:
[1] IPCC: Climate Change 2007, IPCC Fourth Assessment Report Intergovernmental Panel on Climate Change,
Cambridge University Press, Cambridge, 2007.
[2] van der Laan-Luijkx, I. T., Karstens, U., Steinbach, J., Gerbig, C., Sirignano, C., Neubert, R. E. M.,
van der Laan, S., and Meijer, H. A. J.: CO2, δO2/N2 and APO: observations from the Lutjewad, Mace Head and F3
platform flask sampling network, Atmos. Chem. Phys., 10, 2010.
[3] Minejima, C., Kubo, M., Tohjima, Y., Yamagishi, H., Koyama, Y., Maksyutov, S., Kita, K., and Mukai, H.:
Analysis of ΔO2/ΔCO2 ratios for the pollution events observed at Hateruma Island, Japan, Atmos. Chem. Phys.
Discuss., 11, 15631-15657, doi:10.5194/acpd-11-15631-2011
[4] Sturm, P., Leuenberger, M., Valentino, F. L., Lehmann, B., and Ihly, B.: Measurements of CO2, its stable isotopes,
O2/N2, and 222
Rn at Bern, Switzerland, Atmos. Chem. Phys., 6, 2006.
[5] van der Laan, S., Neubert, R. E. M., and Meijer, H. A. J.: Methane and nitrous oxide emissions in The Netherlands:
ambient measurements support the national inventories, Atmos. Chem. Phys., 9, 9369-9379, doi:10.5194/acp-9-9369-
2009, 2009.
[6] van der Laan, S., Karstens, U., Neubert, R. E. M., van der Laan-Luijkx, I., and Meijer, H. A. J.: Observation-based
estimates of fossil fuel-derived CO2 emissions in the Netherlands using Δ14
C, CO and 222
Radon. Tellus B, 62: 389–402.
doi: 10.1111/j.1600-0889.2010.00493.x, 2010.
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Developing high precision CO2 monitoring technique in India: preliminary
results
Yogesh K. Tiwari, K. Ravi Kumar, Aparna Krishnamurthy
Indian Institute of Tropical Meteorology, Pune, India
Developing countries account for ~73% of the global emissions CO2 [Raupach et. al, 2007].
According to the Energy Information Administration (EIA), the CO2 emissions are expected to
increase by 1.8 percent annually between 2004 and 2030. The Carbon Dioxide Information
Analysis Center (CDIAC) estimates the total fossil fuel CO2 emissions from India as 189 TgC in
1990, 324 TgC in 2000, 385 TgC in 2005 & 508 TgC in 2009, and the annual rate of increase is
~7% per year during 2005-2009 [Boden et al, 2010]. Most of the models that participated in the
Transcom programme [Gurney et al., 2004] show large uncertainties over regions of poor data
coverage. The number of stations taking regular measurements of atmospheric CO2 in India are
on the order of one or two. There have been very little monitoring of atmospheric CO2
concentration over India to date [Bhattacharya et al, 2009]. To provide regular data of
atmospheric CO2, it is strongly agreed that there ought to be a network of stations [Tiwari et al,
2011a]. In order to do so, we have started an observing site at Sinhagad (SNG) located near the
west coast of India and about 1600 m above sea level. Regular sampling at SNG (lat=18.35,
lon=73.75) started in November 2009, with air samples being collected weekly. SNG receives
marine air during Indian summer monsoon months (JJA) and terrestrial air during winter months
(DJF). We have established a Gas Chromatograph (GC) lab at the Indian Institute of Tropical
Meteorology Pune India [Tiwari et al, 2011b] with two detectors Electron capture detector
(ECD) and flame ionization detector (FID). We present CO2 concentration data and compare
them with those obtained from model simulations.
References:
S. K. Bhattacharya; D.V. Borole; R. J. Francey; C. E. Allison, et al. Trace gases and CO2 isotope records from Cabo
de Rama, India. Current Science, 97, 1336-1344, 2009
T. Boden; G. Marland; R. J. Andres. National CO2 emissions from fossil-fuel burning, cement manufacture, and Gas
Flaring: 1951-2007, Carbon Dioxide Insformation Analysis Centre (CDIAC), Oak Ridge National Lab, doi
10:3334/CDIAC/00001_v2010., 2010
K. R. Gurney; et al. Transcom 3 inversion intercomparison: Model mean results for the estimation of seasonal
carbon sources and sinks. Global Biogeochem. Cycles., 18, GB1010, 2004
M. Raupach; G. Marland; P. Cias; C. Le Quere; et al. Global and regional drivers of accelerating CO2 emissions,
PNAS, doi: 10.1073/pnas.0700609104
Y. K. Tiwari; P. K. Patra; F. Chevallier; R. J. Francey; et al. CO2 observations at Cape Rama India for the period of
1993-2002: implications for constraining Indian emissions, 2011, (under review)
Y. K. Tiwari; K. Ravi Kumar. Glass flask air sample analysis through Gas Chromatography in India: Implications
for constraining CO2 surface fluxes, WMO GAW report 194, pp 112-116, 2011
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Experimental estimation of line broadening of Carbon dioxide monitoring
Jeongsoon Lee
1, Jin Bok Lee
1, Dong Min Moon
1, Jin Seog Kim
1
1Korea Research Institute of Standards and Science (KRISS), Division of Metrology for Quality Life,
P.O.Box 102, Yusong, Daejeon, Republic of Korea
Email: [email protected]
The global warming requires an observation of green house gases accurately and precisely. It is well
known that the carbon dioxide (CO2) is the green house gas which contributes highly global warming.
(IPCC 2007). Currently, Non-Dispersive Infra-Red(NDIR) analyzer is used for monitoring the
background CO2 atmosphere. The analyzer has excellent stability and repeatability compared to others.
However it requires at least 4 points calibration and 4 standard mixtures. Therefore, the application of
a Cavity Ring-Down Spectroscopy(CRDS) increases recently. A CRDS analysis has several
advantages of excellent linearity and reproducibility of a level(0.1 µmol/mol) as well as outstanding
stability.
In this work it is studied the CRDS measurement of CO2. Its repeatability, linearity, and
reproducibility were investigated. For the purpose of investigating the line broadening effects, we
have prepared 6 standard gases. A group of cylinders among them were prepared with the gravimetric
method and another group of cylinders were prepared by way of air sampling. As a result, it was
found that CRDS should be calibrated the mixtures with the same composition of air to monitor
ambient CO2 accurately. Consequently this study provide an effective estimation of absorption line
broadening of Carbon dioxide monitoring with CRDS.
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Tower-based CRDS greenhouse gas measurements in an urban environment:
Calibration, field tests, and results from the INFLUX project.
Natasha Miles1, Scott Richardson
1, Thomas Lauvaux
1, Laura McGowan
1,
Daniel Sarmiento1, Kenneth Davis
1, Jocelyn Turnbull
2, Colm Sweeney
2,
Kevin Gurney3, Maria Cambaliza
4, Paul Shepson
4
1The Pennsylvania State University
2NOAA ESRL GMD / University of Colorado
3Arizona State University
4Purdue University
Independent verification of anthropogenic greenhouse gas emissions is an emerging need as
legislation to regulate greenhouse gas emissions becomes increasingly likely. However,
relatively few atmospheric measurements using towers above the surface layer have been
attempted in urban environments. As part of the INFLUX project, CO2, CH4 and CO mixing
ratios are measured using wavelength-scanned cavity ringdown spectroscopy (Picarro, Inc.)
at two towers separated by 40 km in Indianapolis, Indiana, USA, with ten additional
instruments to be deployed in Fall 2011. We first describe calibration, laboratory, and field
testing of the instruments, including an 11-day drift test and a 3-month comparison of co-
located instruments. We then present case studies of multi-species data, with comparison to
forward modelling results. For April – July 2011, histograms of the inter-site differences in
CO2, CH4, and CO mixing ratios, measured at > 100 m AGL, are shown in Fig. 1. While
CH4 is evenly distributed about zero, both CO2 and CO are preferentially higher at the urban
site, with median inter-site differences of 2.4 ppm and 8.1 ppb, respectively.
Figure 1. Histograms of daily inter-site differences in mixing ratios at 3 - 4 pm LST. Vertical
lines indicate the medians. The sites are the initial two tower sites of the INFLUX project: Site
01 is southwest of Indianapolis in a rural area, whereas Site 02 is on the western edge of the city.
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JMA aircraft observation using a cargo aircraft C-130H
Yousuke Sawa1, K. Tsuboi1, H. Matsueda1, Y. Niwa1, M. Nakamura2, D. Kuboike2, K. Saito2, H. Oomori2, S. Iwatsubo2,
H. Nishi2, Y. Hanamiya2, K. Tsuji2, and Y. Baba2
1 MRI, 1-1 Nagamine, Tsukuba, 305-0052 Japan
2JMA, 1-3-4 Ohtemachi, Chiyoda-ku, Tokyo, 100-8122 Japan
Corresponding author: [email protected]
Japan Meteorological Agency (JMA) started an operational aircraft observation of greenhouse gases as a new atmospheric monitoring activity in 2011. A cargo aircraft C-130H in Japan Ministry of Defence is used for the flask sampling observation during a regular flight between Tokyo and Minamitorishima (MNM) once a month. The air samples are collected during a cruising flight at about 6 km over the western North Pacific as well as a descending to MNM. After the flight, we measure 4 trace gas concentrations of carbon dioxide (CO2), methane (CH4), carbon monoxide (CO), and nitrous oxide (N2O). In collaboration with Meteorological Research Institute (MRI), test flights using the C-130H were made in 2010 to establish a flask sampling procedure on board the aircraft. In addition, a high-precision measuring system for the trace gas analyses was newly developed. In this presentation, the details of sampling and analysis instrumentations for the JMA aircraft observation and their performances are introduced.
Sample air in the C-130H was taken from an air-conditioning blowing nozzle upstream of the recirculation fan to avoid the contamination of cabin air. We prepared a 1.7-L titanium flask of which internal surface is coated by silicon. Air samples are pressurized into the flasks by a manual diaphragm pump to an absolute pressure of about 0.4MPa. The storage tests for the flask samples during several days were repeated to ensure the stability of trace gases until analyses. Specially coordinated flights at a low altitude of 1000ft over MNM were made using the C-130H to compare with the ground-based measurements from the MNM monitoring system in JMA. It was confirmed that our aircraft sampling procedure was suitable for the precise measurements of trace gases.
The JMA/MRI developed the automated measuring system consisting of a NDIR analyzer (Licor, LI-7000) for CO2 as well as recently advanced spectroscopy instruments of WS-CRDS analyzer (Picarro, G2301) for CO2 and CH4, VURF analyzer (Aero-Laser, AL5002-AIR) for CO, and off-axis ICOS analyzer (Los Gatos, N2O/CO Analyzer) for N2O and CO. High-precision analyses of our system were estimated by the experiments using standard gases and natural air. In addition, our measurements were evaluated from comparison exercises with the conventional GC methods to ensure the consistency of other observational datasets from the JMA monitoring activities.
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Measuring CO2 and H2O Fluxes from Fast Mixing Ratio without a Need
for Density Corrections
George Burba1, Andres Schmidt
2, Russell Scott
3, Taro Nakai
4, James Kathilankal
1, Gerardo
Fratini1, Chad Hanson
2, Beverly Law
2, Dayle McDermitt
1, and Robert Eckles
1
1 LI-COR Biosciences, Lincoln, NE, United States
2 Oregon State University, Corvallis, OR, United States
3 Agricultural Research Service, USDA, Tucson, AZ, United States
4University of Alaska, Fairbanks, AK, Unites States
Enclosed gas analyzer with short intake tube is a blend of a traditional long-tube
closed-path design and a traditional open-path design. Analogous to closed-path, the enclosed
design leads to minimal data loss during precipitation events and icing, and it does not have
surface heating issues. Analogous to the open-path design, the enclosed design has good
frequency response due to the short intake tube, does not require frequent calibration, needs
minimal maintenance, and could be low power when used with short intake tube.
In addition to these advantages, enclosed design could provide measurement of fast
mixing ratio, or dry mole fraction, because native density measurements can be converted to
mixing ratio units using fast measurements of temperature, water vapor and pressure inside
the sampling cell. Fast mixing ratio implies that the thermal expansion and water dilution of
the sampled air have been accounted for in such a conversion. Thus, no density corrections
are required to compute fluxes when the fast mixing ratio is used. Such a way of calculating
fluxes has been used frequently with traditional closed-path analyzers (e.g., LI-6262 and LI-
7000), because fast fluctuations in the air temperature of the sample were attenuated in the
long intake tube, and because water vapour was simultaneously measured and dry mole
fraction was output from the instrument. In an enclosed design, such as the LI-7200 used with
short tube, most but not all of the fast temperature fluctuations are attenuated, so calculating
fluxes using the mixing ratio output of such an instrument requires validation.
The CO2 and H2O Eddy Covariance fluxes of from nine experiments with new LI-
7200 enclosed analyzer were examined here: six deployments of the Ameriflux Roving
Intercomparison Station in California, Arizona, New Mexico and Oregon; one deployment at
a USDA flux site in Arizona; one deployment in University of Alaska-Fairbanks site in
Alaska, and one deployment at the LI-COR flux test facility in Nebraska. Fluxes were
computed in two ways: (i) via the traditional way using the density corrections, and (ii) via a
mixing ratio output from the instrument without applying the density corrections. The results
of these comparisons have important implications for future gas flux measurements, because
avoiding half-hourly or hourly density corrections could help to minimize at least two kinds
of uncertainties: (i) the uncertainties associated with correcting the product of fast
covariances of gas density using sensible and latent heat flux calculated over half-hour or an
hour; and (ii) the uncertainties in the magnitudes of the sensible and latent heat fluxes used in
correcting gas flux.
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A level one ICOS atmospheric station in Eastern France
Marc Delmotte1, Olivier Laurent
1, Sébastien Conil
2, Olivier Corpace
3, Stephan Baum
4, Lynn
Hazan1, Ingeborg Levin
5, Michel Ramonet
1, Martina Schmidt
1, Cyrille Vuillemin
1 and
Philippe Ciais1
1 Laboratoire des Sciences du Climat et de l’Environnement, Gif sur Yvette, France
2 OPE, ANDRA, Bure, France
3 IRFU, CEA, Gif sur Yvette, France
4 MPI-BGC, Jena, Germany
5 University of Heidelberg, Heidelberg, Germany
Within the framework of the ICOS (Integrated Carbon Observation System) project, a
new atmospheric continuous monitoring station has been set up in Eastern part of France
(Houdelaincourt, 48.33° N, 5.30° E, 392 m a.s.l) in cooperation with ANDRA. A 120 meter
tower has been erected on site and measurements are conducted on three levels (120, 50 and
10m) for greenhouse gases (CO2, CH4, N2O) and meteorological parameters (wind speed and
direction, temperature, relative humidity as well as atmospheric pressure). Additional useful
parameters such as 14
C of CO2, CO, Radon, CO2 flux measurements and planetary boundary
layer height (from Lidar) are also recorded for a full data interpretation while flask samples
are collected for quality control of the continuous analysers and additional compounds
measurement (O2/N2, H2, SF6 and CO2 stable isotopes). With its complete set of
instrumentation, the OPE station is nowadays the unique level one ICOS station. The whole
set of instrumentation has been integrated by LSCE and IRFU in an automatic air sampling,
calibration and supervision system which is foreseen as the model for the future ICOS
“labelled” atmospheric station. Since May 2011, the OPE station is taking part in the ICOS
demonstration experiment.
In the present work we will present the new station as well as the integrated system
and show the first results obtained during the first months of the demonstration experiment.
Figure 1: The OPE ICOS level one atmospheric station.
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Four years of in situ atmospheric O2 and CO2 data from
Weybourne Atmospheric Observatory, Norfolk, United Kingdom
Philip A. Wilson, Andrew C. Manning, Michael Patecki, Alex J. Etchells and Andrew J. Macdonald
School of Environmental Sciences, University of East Anglia, Norwich, NR4 7TJ, UK
We present a four year data record of atmospheric measurements of oxygen (O2) and carbon
dioxide (CO2) collected at Weybourne Atmospheric Observatory (WAO) on the north Norfolk coast
(52.95°N, 1.12°E) in the UK. In situ, continuous measurements cover the period from the system’s
inception in October 2007 to the present day.
CO2 measurements are made using a commercially available NDIR CO2 analyser, a Siemens
‘Ultramat 6E’. O2 measurements are made utilising an electrolytic reaction on the surface of lead
fuel cells in an ‘Oxzilla II’ analyser from Sable Systems. A gas handling system similar to that used
by Stephens et al.[2007] is employed to draw air in from an aspirated inlet at the top of a 10 m a.g.l.
tower and then controls flow rate and pressure before the sample air reaches the two analysers in
series. A rigorous calibration regime similar to that described by Keeling et al.[1998] is used to
maintain the accuracy and precision of the data collected and WAO participates in both the
‘Cucumber’ and WMO round robin intercomparison programmes to ensure the compatibility of our
data compared to other global stations.
We present the 4 year record of our data for both species and that for Atmospheric Potential
Oxygen (APO), which combines the signals for O2 and CO2 in such a manner that APO is
insensitive to terrestrial processes and thus illustrates, for the most part, only influences due to
oceanic processes.. We discuss the seasonal cycle observed at the station, inter-annual variability,
and some interesting synoptic events.
Figure 1. Atmospheric CO2 (top; in ppm), O2 (middle; in per meg) and APO (bottom; in per meg)
concentrations as measured at WAO in 2011. Y-axis scales have been adjusted so that molar
variations are visually comparable for all these species.
References: Keeling, R. F., A. C. Manning, E. M. McEvoy, and S. R. Shertz, Methods for measuring changes in
atmospheric O2 concentration and their application in southern hemisphere air, Journal of
Geophysical Research-Atmospheres, 103 (D3), 3381-3397, 1998.
Stephens, B. B., P. S. Bakwin, P. P. Tans, R. M. Teclaw, and D. D. Baumann, Application of a differential
fuel-cell analyzer for measuring atmospheric oxygen variations, Journal of Atmospheric and
Oceanic Technology, 24 (1), 82-94, 2007.
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New improvements in the Izaña (Tenerife, Spain) global GAW station in-
situ greenhouse gases measurement program.
A.J. Gomez-Pelaez1, R. Ramos
1, V. Gomez-Trueba
1,2, R. Campo-Hernandez
1, E.
Dlugokencky3, and T. Conway
3
1 Izaña Atmospheric Research Center, Meteorological State Agency of Spain (AEMET)
2 Air Liquide Canarias
3 NOAA-ERSL-GMD
We present the main improvements in the in-situ Izaña (Global GAW station) greenhouse
gases (GHGs) measurement program during the last few years. First, we present the
calibration schemes for the GC-ECD used to measure atmospheric N2O and SF6, their
calibration processing and statistics, and the software developed for ambient data processing
taking into account the hierarchy of calibrations. Also, the in-situ Izaña N2O and SF6 series
(from June 2007 till July 2011) are showed. Second, we present the software developed to
compare in-situ Izaña GHG measurements with co-located NOAA flasks, and summarizes
the results of such comparisons for CO2, CH4, N2O and SF6. Third, some novelties
concerning the in-situ Izaña CH4 measurements are detailed. Finally, updates of the in-situ
CO2 and CH4 Izaña time series are showed.
Figure 1. Daily night means (20:00-08:00 UTC) of Izaña in-situ carbon dioxide
measurements.
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Update on the continuous CO2/CH4 measurement at Zotino Tall Tower Observatory (ZOTTO) in Central Siberia
Jan Winderlich1, Jošt V. Lavrič1, Huilin Chen1,2, Christoph Gerbig1, Alexey V. Panov3, and Martin Heimann1
1 Max Planck Institute for Biogeochemistry, Jena, Germany 2 NOAA Earth System Research Laboratory, Boulder, CO, USA
3 Sukachev Institute of Forest, SB RAS, Krasnoyarsk, Russian Federation
Email: [email protected], [email protected]
The Zotino Tall Tower Observatory (ZOTTO, www.zottoproject.org.), located in central Siberia next to the Yenisei River (60°N, 90°E), was equipped with a cavity ring-down spectroscopy CO2/CH4/H2O analyzer in April 2009. Assessing the quality through regular target tank measurements prove the system to be remarkably stable over two years continuous operation (Figure 1).
Figure 1. Target tank time series; the solid (dashed) lines indicate the means (standard deviations)
The installation of air buffer volumes in each sample line allows the continuous measurement of six tower levels from 4 m to 301 m height with only one analyzer. The measurement system requires no drying of the sample air. Instead, the simultaneous water vapor measure-ments are used to correct the dilution and pressure-broadening effects with a repeatability of 0.03 ppm for CO2 (0.3 ppb for CH4). The applied correction algorithms have been shown to remain stable over time. Taking into account the measurement uncertainty of the target gas, the calibration gases, and the water correction, the system has a measurement precision (accuracy) of 0.04 ppm (0.09 ppm) for CO2 and 0.3 ppb (1.5 ppb) for CH4, which is compliant with the WMO recommendations. Despite the remote location of the system, the maintenance time adds up to only 3.7 % of the operation time. References: Winderlich, J., Chen, H., Gerbig, C., Seifert, T., Kolle, O., Lavrič, J. V., Kaiser, C., Höfer, A., Heimann, M.: Continuous low-maintenance CO2/CH4/H2O measurements at the Zotino Tall Tower Observatory (ZOTTO) in Central Siberia, Atmos. Meas. Tech., 3(4), 1113-1128, doi:10.5194/amt-3-1113-2010, 2010.
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Atmospheric Observation Network for New Zealand
Gordon Brailsford, T. Bromley, K Currie, M. Evans, M. Harvey, M. Kotkamp, K. Lassey, J.
McGregor, R. Martin, R. Moss, S. Mikaloff-Fletcher, S. Nichol, J. Robinson, V Sherlock, D
Smale, K Riedel and A Gomez2.
1 National Institute of Water and Atmospheric Research
PO Box 14901, Wellington, New Zealand
2 Victoria University, Wellington New Zealand
Atmospheric observations have been a key component of research at NIWA, the first
observations starting in 1954 with Atmospheric 14
CO2, and followed later with the first
southern hemisphere continuous CO2 measurement programme at Makara, Wellington in
1969 and relocated to Baring Head, Wellington in 1972. The programme has now expanded
to include non-CO2 greenhouse gases and other tracers that assist in understanding both the
carbon cycle and atmospheric chemistry. In recent years the observation network has been
expanded to include total column and in situ observations at Lauder in Central Otago, a
surface pCO2 time series out to the Sub Antarctic Surface Waters off Dunedin. Antarctic
observations are made routinely at Arrival Heights and periodic transects are collected across
the Pacific between New Zealand and the USA and more recently to Japan. The current scope
of observations and the future directions will be discussed
file:///C:/Users/Brailsford/Local%20Settings/Temp/XPgrpwise/[email protected]
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Towards a UK-ICOS programme: Existing and underway atmospheric observations on the UK mainland, South Atlantic and Arctic
David Lowry1, Andrew C. Manning2, John B. Moncrieff3, Rebecca E. Fisher1, Mathias
Lanoisellé1, Philip A. Wilson2 and Euan G. Nisbet1
1 Royal Holloway, University Of London, Egham TW20 0EX, UK 2 School of Environmental Sciences, University of East Anglia, Norwich, NR4 7TJ, UK
3 School of Geosciences, University of Edinburgh, Edinburgh, EH9 3JN, UK
The United Kingdom is working towards a programme which will significantly contribute to the European Union’s Integrated Carbon Observation System (ICOS). The UK’s Natural Environment Research Council (NERC) is calling for a new £8M consortium proposal, and a £2M measurement project has been recently funded by the UK Government’s Department of Energy and Climate Change (DECC). ICOS aims to provide the long-term observations required to understand the present state and predict future behaviour of the global carbon cycle and greenhouse gas emissions in Europe and adjacent regions, and to monitor and assess carbon sequestration and greenhouse gas emission reduction activities, including attribution of sources and sinks by region and sector.
UK infrastructure and ongoing projects in atmospheric greenhouse gas observation includes four atmospheric stations on the UK mainland measuring in situ CO2 concentrations: Angus, Dundee (56.56°N, 2.99°W; UEDIN); Egham, London (51.43°N, 0.56°W; RHUL); Weybourne, Norfolk (52.95°N, 1.12°E; UEA); and Barra, Scottish Hebrides (57.00 N, 07.47 W). These stations have CO2 records varying in length up to sixteen years, and each also measures a suite of additional greenhouse and greenhouse-related atmospheric species. In addition, RHUL runs remote high precision CRDS-equipped stations on East Falkland Island (51.72°S, 57.85°W) and Ascension Island (7.97°S, 14.40°W). Flask samples are also collected from these stations, as well as from Spitsbergen and Cyprus, and from Cape Point, South Africa (34.35°S, 18.49°E), the latter in collaboration with the South African Weather Service. In 2012, we will initiate flask sampling from Falklands and Ascension for a wider range of species, and in situ measurement from Teriberka, Russia (69.2°N, 35.1°E), the latter in collaboration with Main Geophysical Observatory, St. Petersburg.
Laboratory infrastructure for atmospheric greenhouse gas measurement includes the Greenhouse Gas Laboratory at RHUL and the Carbon Related Atmospheric Measurement (CRAM) Laboratory at UEA. RHUL has two Trace Gas CF-IRMS instruments for rapid high-precision δ13CCO2 and δ13CCH4 analysis, continuous CRDS measurement for CO2 and CH4, and PP1 measurement of CO and H2, as well as older NDIR, GC-FID and RGA systems. Records date from mid-1990s. The CRAM Laboratory is equipped with an NDIR CO2 analyser, vacuum ultraviolet O2 analyser, gas chromatograph with FID (CH4 and CO) and ECD (N2O and SF6), and a mass spectrometer (Ar/N2 ratios). In addition, UEA runs the Calibration Cylinder Filling Facility (CFF) which can prepare dry working and reference standards at sub- and above-ambient concentration for a range of species, at pressures up to 300 bar.
Campaign work is carried out at locations such as Hong Kong, aircraft sampling above the UK, and Arctic locations in Canada, Finland and Russia. These campaigns involve collecting air samples in flasks or bags for subsequent laboratory analysis of atmospheric concentrations (CO2, CH4, N2O, SF6, CO, H2, Rn, O2, and Ar/N2) and isotopic ratios (δ13CCO2 and δ13CCH4).
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Towards continuous measurements of CO and N2O at Cape Grim
L. Paul Steele, Zoë M. Loh, Rebecca Gregory, Darren A. Spencer, and Paul B. Krummel
Centre for Australian Weather and Climate Research / CSIRO Marine & Atmospheric
Research, Private Bag No. 1, Aspendale, Victoria 3195 Australia
Gas chromatography with electron capture detection (GC/ECD) has been the mainstay
analytical technique for studying the trends, seasonal cycles, and distribution of atmospheric
nitrous oxide (N2O). Much has been learned about the atmospheric budget of N2O by the
analysis of such measurements (see, for example Nevison et al., 2011, and references
therein). But the uncertainties in the global budget of atmospheric N2O remain stubbornly
large. Fast response, continuous, and highly precise measurements of N2O based on the use
of a quantum cascade laser (QCL)-based instrument (eg. McManus et al., 2008) flown on a
research aircraft, have recently revealed compelling new evidence for strong tropical
emissions of N2O (Kort et al., 2011).
Gas chromatography with a heated mercuric oxide detector has been a major technique in the
study of tropospheric carbon monoxide (CO), especially in remote, clean air locations. But
the nature of the non-linear instrument response has made this technique difficult to maintain
in the long-term. Again, a QCL-based instrument can offer fast response, truly continuous,
and very precise measurements of CO, with very low detection limits, and a very wide
measurement range. The advantages of using such a technique at Cape Grim will be
described, as well as some results from our initial experiments with such an instrument.
References:
E.A. Kort; P. K. Patra; K. Ishijima; B. C. Daube; R. Jiménez; J. Elkins; D. Hurst; F. L.
Moore; C. Sweeney; S. C. Wofsy. Tropospheric distribution and variability of N2O:
Evidence for strong tropical emissions. Geophys. Res. Lett., 38, L15806,
doi:10.1029/2011GL047612, 2011.
J.B. McManus; J.H. Shorter; D.D. Nelson; M.S. Zahniser; D.E. Glenn; R.M. McGovern.
Pulsed quantum cascade laser instrument with compact design for rapid, high sensitivity
measurements of trace gases in air. Applied Physics B, 92, 387-392, 2008.
C.D. Nevison; E. Dlugokencky; G. Dutton; J.W. Elkins; P. Fraser; B. Hall; P.B. Krummel;
R.L. Langenfelds; S. O’Doherty; R.G. Prinn; L.P. Steele; R.F. Weiss. Exploring causes of
interannual variability in the seasonal cycles of tropospheric nitrous oxide. Atmos. Chem.
Phys., 11, 3713-3730, 2011.
mailto:[email protected]
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China National Report
Ling-Xi Zhou* and Colleagues
Chinese Academy of Meteorological Sciences (CAMS), China Meteorological
Administration (CMA), 46 Zhongguancun Nandajie, Beijing 100081, China
[email protected], [email protected]
CMA represents the WMO Commission for Atmospheric Sciences in China and is deeply
involved in the GAW programme of the WMO. The CMA initiate/run a Central GHG &
Tracers Lab in Beijing and a number of background monitoring stations in China, for
example Mt. Waliguan in remote western China (one of the 28 GAW baseline stations) and
the long greenhouse gas record contribute to the WDCGG and the Globalview data products.
The CMA has strong working relationship with global measurement community within the
GAW and has long-term bilateral cooperation with the NOAA/ESRL and other National
Meteorological and Hydrological Services (NMHSs) and partners. To serve the needs of the
expending Chinese measurement communities and better contribute to the global network,
one of the CMA’s capability and effort is to set up a National CCL with linkage to the WMO
CCLs. Since 2009, in-situ high accuracy measurement of atmospheric CO2 and CH4 mixing
ratios by custom designed systems using CRDS technique has been carried out at the five
background stations in China. The data was well calibrated relative to international standard
scale, which is essential to the integrated database and inverse flux estimations.
Figure 1. Atmospheric CO2 (left) and CH4 (right) record by in-situ CRDS at the five Chinese
GAW stations (WLG, SDZ, LAN, LFS and XGL) began in January 2009.
广东帽峰山
青海瓦里关
浙江临安
黑龙江龙凤山
北京上甸子
中国气象局现有的7个大气本底站
湖北金沙
新疆阿克达拉
云南香格里拉
CMA’s GHG station
WLG
SDZ
LFS
LAN
XGLL
JSA
HYA
AKDL
广东河源广东帽峰山
青海瓦里关
浙江临安
黑龙江龙凤山
北京上甸子
中国气象局现有的7个大气本底站
湖北金沙
新疆阿克达拉
云南香格里拉
CMA’s GHG station
WLG
SDZ
LFS
LAN
XGLL
JSA
HYA
AKDL
广东河源
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GREENHOUSE GASES BACKGROUND STATIONS IN BRAZIL COAST
Viviane F. Borges1, Luciana V. Gatti
1, Alexandre Martinewski
1, Caio S.C. Correia
1,
Luana S. Basso1, Lucas G. Domingues
1, Emanuel Gloor
2, John B. Miller
3
1Instituto de Pesquisas Energéticas e Nucleares – IPEN/USP, São Paulo, Brazil.
2University of Leeds, Leeds, United Kingdom.
3National Oceanic and Atmospheric Administration – NOAA, Boulder, Colorado, USA.
[email protected] and [email protected]
Since Amazonia represent 50% of tropical forest in the world, the absence of measures in
the tropics and the Amazon, generate significant uncertainty in the Climate models predictions.
Thus were established two locations along the Brazilian coast and these were compared with to
NOAA's global stations in the Atlantic Ocean, Ascension Islands (ASC: 8°S, 14ºW) in the South
Atlantic Ocean (SAO) and Barbados (RPB: 13°N, 59ºW) in the North Atlantic Ocean (NAO). The
two background Brazil stations are located in northeast coast were Natal, RN (NAT: 5°S, 35°W),
and Salinópolis, PA (SAL: 1°S, 47°W). The air sampling was performed on the surface, using a pair
of 2.5l glass flasks. Air samples were analyzed in the Laboratory of Atmospheric Chemistry of
IPEN. It was calculated back trajectories using HYSPLIT1 model to determinate the origin and
seasonality of air masses that arrive there. Two pairs of flasks are sampled at the same time for
IPEN and NOAA, allowing a continuous comparison program.
The Figure 1 (A) shows the study sites along the Brazilian coast, Natal and Salinópolis and
the NOAA global stations, Ascension and Barbados, and (B) the CO2 concentrations found in NAT
and SAL (IPEN) and ASC and RPB from NOAA network.
Figure 1: (A) shows the study sites and global stations, and (B) the concentrations for CO2 found in
NAT and SAL, comparing them with the global stations.
The mean concentrations found were: SAL: 388ppm CO2, 1790ppb CH4, 98ppb CO, 324ppb
N2O and 7ppt SF6; and NAT: 389ppm CO2, 1777ppb CH4, 78ppb CO, 324ppb N2O and 7ppt SF6,
generally between the two global stations concentration. CO2 in NAT presents no seasonality and at
SAL follows Barbados seasonality approximately. Observing the concentrations between January to
April it is like a average between ASC and RPB. From April to July were lower than the ASC,
meteorological studies indicated low wind speed for this period and south origin for the air masses.
References: 1DRAXLER, R.R.; ROLPH, G.D., 2003. HYSPLIT (Hybrid Single-Particle Lagrangian Integrated Trajectory) Model.
Website: . NOAA Air Resources Laboratory, Silver Spring, MD.
Acknowledgment: IPEN, NERC, NOAA and FAPESP.
mailto:[email protected]
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ASSESSMENT OF CHEMICAL COMPONENTS PRESENT IN THE
ATMOSPHERIC AEROSOL
Sapana Gupta
(IIASA YSSP-2009)
Central Institute of Technology, Raipur CG, India
Email: [email protected]
Key words: Chemical components of PM, Aerosol, Health effects, PCA,
Particulate matter (PM) has been widely studied in recent years due to its potential
health impact and need for its control. A study of the atmospheric particulate matter
(APM) and associated anions present in aerosol has been carried out for the city of Raipur
India using principal component analysis (PCA) and positive matrix factorization
(PMF) models.The particulate matter can pass through the natural protective mechanism
of human respiratory system and plays an important role in genesis and augmentation of
allergic disorders. Sources of air pollution in the area and the unique problem arising out
of the emission from the vehicles, industries, etc. have been described. Ambient air
quality was monitored along with micrometeorological data and the results are discussed.
The status of air pollution in the area has been evaluated and a questionnaire survey was
conducted to estimate the allergic symptoms and exposure to assess the respiratory
disorders. The data are analysed to evaluate the critical situation arising out of the
emission of air pollutants and the impact on human health due to respirable diseases
(RDs) to middle class sub-population in the area are assessed. A strategic air quality
management plan has been proposed. The particulate matters (PM10 and PM2.5) in the
ambient air at residential site of Raipur city were collected using sequential
speciation air sampler (Partisol Model 2300, Thermo Sci., USA) equipped with
temperature and humidity sensor. Two types of filters were used for collection of the
PM10 and PM2.5 simultaneously. The teflon and nylon 47-mm filters were used for
the collection of the trace elements (i.e. Al, Si, Ti, V, Cr, Mn, Fe, Ni, Cu, Zn and Pb)
and water soluble ions (i.e. SO42-, NO3
-, Cl-, NH4+, Na+, K+, Mg2+ and Ca2+),
respectively. The PCA and PMF models have shown that the central India particulate
matters is a six-component system: secondary nitrate, crustal material, long-range
transport of regional and marine aerosols, and three anthropogenic sources
(metallurgy, coal combustion and cement manufacture).The seasonal evolution of
the daily contributions confirmed the interpretations of these sources.
Allen, A.G., Nemitz, E., Shi, J.P., Harrison, R.M., Greenwood, J.C. Atmos. Environ. 35,
4581–4591, 2001.
Mouli, P.C., Mohan, V.S., Reddy, J.S. Environ. Monit. Assess. 117, 291–305, 2006.
Mishra, U.C.J. Aerosol Sci. 19, 1165–1169, 1988.
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Atmospheric Carbon Monoxide Measurements at NIWA
Rowena C. Moss
1, Ross J. Martin
1, Gordon W. Brailsford
1
1
NIWA (National Institute of Water and Atmospheric Research Ltd.),
Private Bag 14901, Wellington 6021, New Zealand.
Atmospheric carbon monoxide concentrations have been measured at NIWA since
1989. Recently a Tekran CVAFS (Cold Vapour Atomic Fluorescence
Spectrophotometer) mercury detector was installed at the NIWA Gas Lab to replace
the old Trace Analytic RGD (Reduction Gas Detector) attached to an HP5890 GC.
The CVAFS uses high purity Argon as a carrier on a molecular sieve 5A, 3.x mm OD
packed column, and utilises a heated Mercuric Oxide bed to oxidise the CO before
the detector. The heated zone for the Mercuric Oxide reaction bed is precisely
controlled by the GC inlet control significantly improving baseline stability. Initial
issues with interference from the eluting oxygen peak have been avoided by switching
the oxygen peak out of the airstream before it reaches the detector.
We have found the CVAFS detector to be significantly more sensitive than the old
RGD. The standard deviation of 5 injections of a standard gas (NOAA06 scale
CA03825 at 64.4ppb) has reduced from 2 ppb to less than 0.7 ppb and peak heights
are an order of magnitude higher.
../Local%20Settings/Temp/AppData/Local/Temp/XPgrpwise/[email protected]
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InGOS - Integrated non-CO2 Greenhouse Gas Observing System; a new
European Infrastructure project
Alex Vermeulen1 and Ingeborg Levin
2, Stefan Reimann3, Martina Schmidt
4, Thomas Bange
5,
Peter Bergamaschi6, Albert Bleeker
1, Somon O’Doherty
7, Arjan Hensen
1, Lynn Hazan
4,
Armin Jordan8, Andrew Manning
9, Ivan Mammarella
10, Eiko Nemitz
11, Euan Nisbet
12,
Thomas Röckmann13
, Thorsten Warneke14
1 ECN - Energy research Centre of the Netherlands, Petten, Netherlands
2 Institut für Umweltphysik, University of Heidelberg, Germany
3 EMPA, Dübendorf, Switzerland
4 Laboratoire des Sciences du Climat et de l’Environnement, France
5 IFM-GEOMAR, Kiel, Germany 6 JRC - Joint Research Centre, Ispra, Italy 7 University of Bristol, United Kingdom
8 Max Planck Institute for Biogeochemistry, Germany
9 School of Environmental Sciences, University of East Anglia, United Kingdom
10 University Helsinki, Finland
11 NERC , Edinburgh, United Kingdom
13 Royal Holloway University of London, United Kingdom
13 University of Utrecht, the Netherlands
14 University of Bremen, Germany
InGOS is a new European infrastructure project that will start in October 2011 and will run
for four years. The overall objective of InGOS is to integrate the existing European facilities
for monitoring of non-CO2 greenhouse gases (NCGHGs) in the atmosphere, at ecosystem
flux measurement sites and over the ocean, by developing common quality control and
quality assurance procedures. Moreover, new measurement techniques and instrumentation
will be explored for preparing the integration of NCGHG measurements into ICOS, thus
giving these observations an operational, long-term monitoring perspective.
Specific objectives of InGOS are:
• Quality check and harmonize the "historical" NCGHG observations in Europe,
• Standardize measurements by developing common QC/QA procedures, and prepare for
integration with the ICOS infrastructure
• Provide near-real time access to the atmospheric CH4, N2O, SF6 and H2 data, also
preparing for integration with the ICOS infrastructure
• Provide access to key field stations and installations such as the calibration facilities and
aircraft sampling of flux heterogeneity
• Prepare expansion of the current network with new stations in under sampled regions,
• Improve analysis methods using innovative techniques and strategies,
• Attribute CH4 source categories by advanced isotope techniques,
• Apply sophisticated, high-resolution inverse models to analyze the measurements made in
InGOS and to support further development of the European NCGHG network,
• Link remote sensing data to the in situ network including FTIR XCH4 observations,
mailto:[email protected]
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• Improve NCGHG flux measurements and link European flux towers to the atmospheric
observational network,
• Stimulate atmospheric science knowledge transfer between experts, and between experts
and young scientists,
• Generate a European non-CO2 GHG observation database, which will be made available
to the scientific community and general public via the InGOS Data Centre, in close
connection with the ICOS infrastructure methodology and databases.
http://www.ingos-infrastructure.eu
http://www.ingos-infrastructure.eu/
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Spectroscopic Effects and Eddy Covariance Calculations of Methane Flux
George Burba, Tyler Anderson, Dayle McDermitt, Anatoly Komissarov, Liukang Xu,
Bradley Rienscher, Douglas Allyn, and Kevin Ediger
LI-COR Biosciences, Lincoln, NE, United States
Traditionally, when Eddy Covariance flux is computed, the fast changes in gas
density are correlated with fast changes in vertical wind speed. The measured changes in gas
density happens due to gas flux itself, due to thermal expansion and contraction of the
sampled gas, water vapor dilution, and pressure-related expansion and contraction. These are
standard processes described by Ideal Gas Law and by Law of Partial Pressures, and often are
called density effects. The gas flux is usually corrected for these density effects using Webb-
Pearman-Leuning correction. When gas density is measured by the means of laser
spectroscopy, there are also spectroscopic effects affecting measured gas density depending
on fluctuations in temperature, water vapor and pressure, in addition to the density effects.
The spectroscopic effects are related to changes in the shape of the absorption line due to
changes in gas temperature, pressure and presence of water vapour. These effects are specific
for each specific absorption line, and the measurement technique.
For closed-path gas analyzers, the majority of density effects and spectroscopic
effects could be reduced or eliminated, when: (i) intake tube is very long, (ii) air sample is
dry, and (iii) pressure fluctuations are very small. While minimizing uncertainty related to
density and spectroscopic effects, use of long intake tubes and drying air sample also lead to
significant increase in power demand, and to increased uncertainties due to excess attenuation
of the fluctuations of the gas of interest in the drier. Not drying air sample leads to the need
for applying density correction for dilution, and spectroscopic corrections for gas absorption
due to fast fluctuations in water vapor pressure. For both of these corrections water vapor
should be measured accurately at hi-speed inside the closed-path device, which increases
measurements costs. In addition, present closed-path analyzers based on laser spectroscopy
have to work under significantly reduced pressures, and require powerful pumps and grid
power (600-1500 Watts). Power demands may be reasons why these instruments are often
deployed at locations with infrastructure and grid power, and not where the gas is produced.
Alternatively, open-path design can be very low-power (e.g., 5-10 Watts) permitting
solar-powered deployments, cost-effective permitting an addition of a single new gas
measurement to the present array of CO2 and H2O measurements, and in-situ avoiding
attenuation of gas fluctuations in the intake tube. These features enable long-term deployment
of permanent, portable or mobile open-path flux stations at remote locations with high
production of the gas of interest. However, open-path density and spectroscopic effects
cannot be neglected. Here we propose a new way to account for spectroscopic effects due to
fast fluctuations in air temperature, water vapor and pressure in the same manner as Webb et
al. (1980) proposed a way of accounting for respective density effects. Since both density
effects and spectroscopic effects are known from Gas Laws and HITRAN respectively they
could be incorporated into WPL correction. We use an example of the fast open-path CH4
gas analyzer, LI-7700, yet the proposed approach would also apply to any closed-path design
where fluctuations in temperature, water vapor and pressure are not fully eliminated.
mailto:[email protected]
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Three and a half years of atmospheric CO2 and O2 data from
Ivittuut, Southern Greenland
Marc Delmotte1, Jean-Louis Bonne
1, Jošt Valentin Lavrič
2, Andrew C. Manning
3, Willi
Brand2, Martina Schmidt
1 and Victor Kazan
1
1 Laboratoire des Sciences du Climat et de l’Environnement, Gif sur Yvette, France
2 MPI-BGC, Jena, Germany
3 University of East Anglia, Norwich, United Kingdom
Since autumn 2007, an atmospheric monitoring station has been running at Ivittuut
southern Greenland (61.21°N, 48.17°W). The station is equipped with highly precise
analysers that provide continuous CO2 and O2 records, and a set of meteorological sensors
(temperature, pressure and relative humidity, wind speed and direction). Regular flask
sampling allows for additional measurements of CH4, CO, N2O, H2, and SF6 mixing ratios,
and CO2 isotopes (18
O and 13
C) as well as for an independent quality control of the
continuous records.
In addition to the LSCE automated data treatment chain handling the CO2 data, we have now
also developed a data treatment chain to process our O2 raw data
Quality control and filtering procedures applied for this station will be presented with
an emphasis on the method applied for O2 data treatment. We will show the full records for
CO2 and O2 and discuss the results obtained in terms of inter-annual and seasonal variability
with comparison with other high latitude sites, as well as APO (Atmospheric Potential
Oxygen). A focus on particular synoptic events will also be presented as “case studies” for air
mass origin tracking, using back trajectory models.
Figure 1: CO2 and O2 records at Ivittuut (Southern Greenland)
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An accurate CO2 measurement system for standard gases
using NDIR CO2 analyzer and CRDS 13
CO2 analyzer
K. Katsumata, H. Nara, Y. Tohjima, Y. Takahashi, T. Machida, and H. Mukai
National Institute for Environmental Studies (NIES), Tsukuba, Ibaraki, Japan
Non-dispersive infrared CO2 analyzer (NDIR) is the widely used instruments for measuring
atmospheric CO2 mol fraction because of its high precision, easiness of the operation, and so
on. However, because the NDIR measurements are slightly affected by the isotopic
composition of CO2 (Lee et al., 2006, Tohjima et al., 2009), we should evaluate the isotope
effect when there are differences in the isotopic compositions of CO2 between air samples
and standard gases. At National Institute for Environmental Studies (NIES), mixtures of pure
CO2 gas derived from burned petroleum and purified air are used as primary standard gases
and the their CO2 isotopic composition (13
C = -32 ‰) are lighter than the atmospheric value
(13
C = ~-8 ‰). The isotope effect of our NDIR analyzers, which are calibrated against
above primary standard gases, are estimated to be ranging from 0.04 to 0.08 ppm for the
measurements of CO2 in the air samples (Tohjima et al., 2009). In addition to the air samples,
we need to determine the CO2 mole fractions of more than 200 working standard gases used
for ground-based measurements, airborne measurements, and shipboard measurements every
year. Because these working standard gases, being similar CO2-in-air mixtures to our CO2
standard gases, have rather wide range of 13
C values from -25 ‰ to -35 ‰, the isotope
effects for the NDIR measurements of those standard gases should be evaluated to accurately
propagate the CO2 mole fraction scale. WMO recommends that the isotopic composition of
distributed standard gases should be roughly determined (GAW Report 194). For this purpose,
we have developed a new CO2 measurement system, in which the 13
C isotopic composition is
also determined easily and rapidly together with the NIDR CO2 measurements. We use a
wavelength-scanned cavity ring-down spectrometer (G2101-i, Picarro) for the 13
C
measurements. The analytical precision (1 ) of 13
C value is about 0.15 ‰ (5 min average
value). This result shows the isotope effect for the NDIR measurements can be corrected with
a precision of 0.01 ppm or less.
Reference:
Lee, J.-Y., H.-S. Yoo, K. Marti, D. M. Moon, J. B. Lee, and J. S. Kim (2006), Effect of carbon isotopic
variations on measured CO2 abundances in reference gas mixtures, J. Geophys. Res., 111, D05302,
doi:10.1029/2005JD006551.
Tohjima, Y., K. Katsumata, I. Morino, H. Mukai, T. Machida, I. Akama, T. Amari, and U. Tsunogai (2009),
Theoretical and experimental evaluation of the isotope effect of NDIR analyzer on atmospheric CO2
measurement, J. Geophys. Res., 114, D13302, doi:10.1029/2009JD011734.
WMO, Global Atmosphere Watch, 15th WMO/IAEA Meeting of Experts on Carbon Dioxide, Other
Greenhouse Gases and Related Tracers Measurement Techniques, GAW Report No. 194, WMO TD No. 1553,
(2011)
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Central Calibration Laboratory for Hydrogen:
First Steps
A. Jordan1, B. Steinberg1, R.L. Langenfelds2, L.P. Steele2, P. C. Novelli3, K.Katsumata4, T.Machida4
1 Max Planck Institute for Biogeochemistry, Jena, Germany 2 CSIRO Division for Marine and Atmospheric Research, Aspendale, Australia
3 National Oceanic and Atmospheric Administration, ESRL-GMD, Boulder, USA 4 National Institute for Environmental Studies, Tsukuba, Japan
At the 15th WMO Experts Meeting the Max-Planck Institute for Biogeochemistry (MPI-BGC) has taken over the role of the WMO-GAW Central Calibration Laboratory for molecular hydrogen (H2) measurements. Following the “General Requirements for Central Calibration Laboratories” first activities in this role have been a) to carry out comparisons with independent primary scales, namely the CSIRO, the
NIES and the NOAA scale b) prepare a second set of standards as a backup for the scale c) conduct additional experiments to check the stability of the scale d) and verify the consistency of the scale using a superior detection technique e) provide calibrated reference gas mixtures to measurement groups A comparison using natural air mixtures in 4.5 L stainless steel containers containing 400 to 670 ppb hydrogen have been circulated between MPI-BGC, NOAA and NIES, and for some samples also CMAR. NOAA and the NIES data were in good agreement showing on average 6 ppb and 7 ppb, respectively, lower results than MPI. CMAR results were 17 ppb lower than MPI data. This latter offset has confirmed a stable inter-laboratory difference observed in multiple other comparisons for several years. CMAR has decided to convert their scale to the MPI-2009 scale. A backup set of twelve high pressure H2 in air standards ranging from 200-1200 ppb has been prepared and calibrated. In parallel, some 20 additional mixtures were prepared by diluting a known volume of pure H2 in hydrogen free air to check the stability of the primary standards. As an additional check of the consistency of the primary calibration standard set these standards have been analysed with a GC-Helium Ionization Pulsed Discharge Detector. The observed absolute residuals are on average below 0.5 ppb. Reference: A. Jordan; B. Steinberg. Calibration of atmospheric hydrogen measurements. Atmos. Meas. Tech. 4, 509-521, 2011. www.atmos-meas-tech.net/4/509/2011/
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Overview on ten years of WCC-N2O
H.E. Scheel
Karlsruhe Institute of Technology (KIT), IMK-IFU 82467 Garmisch-Partenkirchen, Germany
The World Calibration Centre for N2O (WCC-N2O) has been established in 2001 as a central GAW facility according to the requirements of the GAW Strategic Plan 2001–2007 (WMO/GAW Report No. 142). Its overall goal is the improvement of the N2O data quality and compatibility within the network. The WCC-N2O is linked to the GAW standard scale maintained by the Central Calibration Laboratory (CCL) for N2O. The WCC-N2O (http://imk.fzk.de/wcc-n2o/) is hosted by the Karlsruhe Institute of Technology (formerly Forschungszentrum Karlsruhe), IMK-IFU, and its activities are conducted under supervision and through funding by the Quality Assurance/Science Activity Centre (QA/SAC) Germany, operated by the German Environment Agency (UBA). As specified by GAW, the major tasks of the WCC-N2O comprise the development of quality control procedures, conducting audits at stations and intercomparison experiments as well as providing training and technical advice to GAW station personnel. After ten years of operation of the WCC-N2O, this presen-tation gives an overview on its activities and achievements. During the entire period, the work conducted in the analytical laboratory was related to com-parisons of N2O standards of different levels in the traceability chain and dedicated to dif-ferent purposes. Presently, eight laboratory standards (range 253 – 358 ppb), recalibrated by the CCL in 2009, establish the link to the GAW N2O scale. They are used for the calibration and surveillance of a suite of 22 gas mixtures. Five of them serve as scale back-up, while 17 are suitable as travelling standards for audits and intercomparisons, usually comprising sets of five cylinders. Moreover, the WCC-N2O took part in three international intercomparison experiments. From the ten system and performance audits conducted since 2002, considerable progress over the years can be noted with respect to network compatibility of N2O measurements by GAW stations. Thanks to the recommendations of GAW meetings as well as updated measurement guidelines including data quality objectives, and based on the acquisition of CCL-calibrated standards, by several stations the link to the GAW N2O scale was improved or newly established. On the analytical side, the audits have revealed significant differences in performance for the gas chromatographic systems, even if equipped with similar instru-mentation. In conclusion, the fulfilment of the GAW N2O data quality objectives still remains a challenge. Details on these issues will be discussed. For completeness, a brief summary of other activities of the WCC-N2O will also be presented.
http://imk.fzk.de/wcc-n2o/�
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Automated analysis of δ13
C, δ2H and δ
18O in CH4 and CO2 from air
samples in flasks using a new twin cryo-trap / GC / IRMS system
Magnus Wendeberg, Martin Strube , and Willi A. Brand,
Max-Planck-Institute for Biogeochemistry (Beutenberg Campus; Hans-Knoell-Str. 10,
07745 Jena, Germany.
A new system for high precision stable isotopes measurements of carbon and
hydrogen in atmospheric methane is being developed at the MPI-BGC in Jena. The
design aims utilizing flask samples from existing sampling programs without the need
of extra samples for methane analysis. Thus, a frugal use of the sample is an important
design criterion. To minimize the total sample volume needed for the analysis, both
CO2 and methane isotopes are measured simultaneously using two Delta V mass
spectrometers. One of the mass spectrometers is used for δ13
C of CO2 and methane
and δ 18
O of CO2, while the second MS is dedicated to measure δ2H of methane.
The iSAAC system (‘isotopic Analysis of Atmospheric Constituents’) consists of an
inlet carousel – capable of holding 16 sample flasks (1-5 L), from which sample gas is
pulled through a series of sample loops mounted within three consecutive Valco
10−port valves. Each 10−port valve takes aliquots from the sample stream, starting
with aliquots for δ13
C and δ 18
O of CO2, followed by δ13
C of methane and last δ2H. In
the latter two cases, the CH4 is pre-concentrated in the respective loops from a larger
sample amount (50-100 mL)1,2
using a newly designed cryo-trap system operating at
variable temperatures down to −130 °C. The use of 10−port valves allows for a
second gas – a precisely calibrated working reference air, to be used in parallel with
the sample according to the Principle of Identical Treatment3.
Using these design principles we aim at robust precision levels of
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A new solution to a standard problem: creating full air standards with precisely referenced isotopic compositions of methane covering the present
and past atmospheric variability in δ13C -CH4
Hinrich Schaefer1 and Myriam Guillevic2, Peter Sperlich2, Christo Buizert2, Theo Jenk2, Thomas Blunier2
1 National Institute of Water & Atmospheric Research Ltd, 301 Evans Bay Parade, Greta Point, Wellington 6021, New Zealand
2 Niels Bohr Institute, Centre for Ice and Climate, Juliane Maries Vej 30, 2100
Copenhagen, Denmark
[email protected], [email protected], [email protected]
In order to understand the changes in atmospheric methane concentrations and to indentify corresponding biogeochemical mechanisms, studying the isotopic composition of methane from atmospheric or ice cores samples is a promising tool. An experimental setup to measure isotopes of atmospheric methane requires calibration with reference gases of known isotopic composition. Unlike CO2 and H2O measurements, there is no universal standard material or procedure to reference methane isotopes (such as a recommendation by the WMO) [1]. The increasing numbers of laboratories measuring methane isotopes and the high precision level reached emphasizes the need to agree on a universal referencing procedure. In most laboratories, the lack of universal methane standards has been overcome by measuring the samples versus full air standards that have previously been referenced in an external laboratory. These reference procedures are laboratory specific and result in limited amounts of reference material. Both points can limit the agreement of different laboratories measuring the same sample. To overcome the referencing problem of methane isotopes, we built a system which enables us to produce full air standards with methane mixtures of precisely referenced δ13C and δD isotopes. The central part of the setup is a combustion and trapping system to quantitatively combust pure methane into CO2 and H2O and to separately trap these combustion products for consecutive δ13C and δD measurement by mass spectrometry. By using methane of two different sources, characterized by two different isotopic compositions, we can mix large amounts of pure methane to any given isotopic value between -40‰ and -52‰ in δ13C or between -170‰ and -320‰ in δD. An aliquot of the characterized methane mixture is then mixed with zero air, which was previously purified from any methane content. By varying the amount of methane and zero air in the target mixture, we are able to control methane concentration with well characterized methane isotopes. References: [1] 15th WMO/IAEA meeting of experts on carbon dioxide, other greenhouse gases and related tracers measurements techniques. GAW report n. 194, 2009.
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14CO2 Processing and Measurement Activities at CU-INSTAAR and NOAA/ESRL
Scott J. Lehman1, Pieter P. Tans
2, John B. Miller
2,3, Stephen A. Monzka
2, Colm Sweeney
2,3,
Arlyn Andrews2,3
, Jocelyn C. Turnbull2,3,4
, John Southon5
1Institute of Arctic and Alpine Research, University of Colorado, Boulder CO USA
2NOAA Earth System Research Laboratory, Boulder CO USA
3Cooperative Institute for Research in Environmental Sciences, University of Colorado,
Boulder CO USA 4now at: Rafter Radiocarbon Laboratory, Lower Hutt NZ
5Keck AMS Facility, University of California, Irvine CA USA
The small radiocarbon fraction of total CO2 (~1:1012
14
C:C) has proven to be an ideal tracer for
its fossil fuel derived component. Unlike all other contributions to the CO2 budget, the fossil
fuel component is devoid of radiocarbon, so that temporal and spatial gradients in recently
added fossil fuel CO2 can be readily identified as radiocarbon gradients provided there is
adequate precision in the measurements. Over large industrialized land areas such as Eurasia
and North America, the use of 14
C to isolate the recently added fossil fuel contribution also
quantifies (by difference) the change in atmospheric CO2 due to uptake and release by the
terrestrial biosphere. Here we will report on a growing number of 14
CO2 processing and
measurement activities within the NOAA Cooperative Global Air Sampling Network, with a
focus on the use of 14
CO2 to constrain the relative and absolute emissions of a large suite of
anthropogenic trace gases measured in the same samples.
Figure 1: Model representations of annual mean
14C (right panel) and the fossil fuel
component of total CO2 (left panel) in the atmosphere near the surface over eastern North
America, from the TM5 transport model. Color scales are fixed according to the mass balance
relationship between 14
C and recently added fossil fuel CO2 of -2.7 per mil/ppm. Small
differences in the color patterns are mostly due to small 14
C gradients arising from the
terrestrial disequilibrium flux of 14
C, which can be independently quantified. CMA and NHA
denote 2 aircraft sampling sites at which we have been making measurements since 2004.
mailto:[email protected]
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Atmospheric 14
C measurement capability at the Rafter Radiocarbon
Laboratory
Jocelyn Turnbull1,2
, Troy Baisden1, Albert Zondervan
1, Christine Prior
1, Gordon
Brailsford3, Rowena Moss
3
1Rafter Radiocarbon Laboratory, GNS Science, Lower Hutt, New Zealand
2CIRES, University of Colorado, Boulder, CO, USA
3NIWA, Wellington, New Zealand
The radiocarbon content of atmospheric CO2 (14
CO2) is an increasingly important tracer
used to quantify the different CO2 sources. Due to the absence of 14
C in fossil fuels,
14
CO2 is perhaps the best way to quantify recently added fossil fuel CO2 in the
atmosphere. The sea-air CO2 flux also has 14
C different from the atmosphere, so
14
CO2 observations can be used to examine the one-way gross CO2 flux out of the
oceans. Yet 14
CO2 continues to be a challenging measurement, due to the very low
abundance of 14
C. Single sample uncertainties are currently, at best, about 2‰, and ~2
liters of whole air are needed (the gas counting method requires ~400L of air for similar
precision). Measurement capacity is also limited, due to the complex processing and
long measurement times required.
The collaboration between NIWA and the Rafter Radiocarbon Laboratory at GNS
Science has a long history of atmospheric 14
CO2 measurements, starting in Wellington
in 1955. In 2010, the Rafter lab obtained a new accelerator mass spectrometer (AMS) for
radiocarbon measurements. A major focus emerging from the upgrade is the opportunity
to expand the atmospheric 14
CO2 capability. We will present our progress toward
demonstrating that verifiable 2‰ precision can routinely be obtained on this instrument.
We will discuss developments in sample preparation and improvements in methodology
to obtain this precision on samples of ~1L of whole air. Finally, we will present progress
on our immediate goal – a replicated high precision Baring Head 14
CO2 record from
archived samples.
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Seeking isotopically suitable CO2 for standard gas
-Production of C isotopic reference gas series from commercially available
liquid CO2 -
Hitoshi Mukai, Yumi Osonoi, Yukio Terao, and Yoko Kajita
Center for Global Environmental Research, National Institute for Environmental Studies,
16-2 Onogawa, Tsukuba, Ibaraki 305-5806 Japan
Carbon isotope ratio of CO2 is important item in terms of C budget study and CO2
concentration analysis. If our standard gas for CO2 concentration is produced using
commercially available liquid CO2, C isotopic ratio is very light (-30 - -40 per mil) compared
to atmospheric CO2 (-9 per mil). Sometimes people want to use standard CO2 gas which has
the same isotopic ratio as atmospheric CO2, because CO2 analysis by NDIR and CRD
technology are known to be affected isotopic composition of standard and sample CO2.
In general to seek isotopically suitable CO2 for standard gas is believed to be hard,
because industrial liquid CO2 is usually come from oil chemical process and natural gas
(methane) process to produce ammonia. On the other hand, natural CO2 from volcanic
activity is known to have different isotope ratio. We confirmed that hot spring water in Ohita
prefecture (JPN) contained high concentration of CO2, which has -10 permil in C isotope
ratio. It must be one of candidates for standard if CO2 is extracted from it on industrial base.
This time we found that one Japanese liquid CO2 producer used limestone as a carbon
source. This liquid CO2 has much heavy isotope ratio (about 2 per mil !). Since this CO2 is
commercially available, we have tried to make CO2 cylinder series of different isotope ratio
from -40 to 2 permil ( -40, -30, -20, -10, 0, 2 permil) by mixing of usual light CO2 (A) come
from natural gas and this heavy CO2 (B). Table 1. Isotope ratio of liquid CO2
Usually a certain amount of CO2 is
needed as gas cylinder to do experimental
works. Therefore, this series must be useful
to test isotopic effect on NDIR and CRD, as
well as isotopic analysis evaluation.
Fig 1 Isotope ratio adjusted CO2 cylinders and mixing method
Delta 13C (permil
vs VPDB)
Delta 18O (permil
VPDB-CO2)
A -42.2 -10.9
B 1.8 -12.8
mailto:[email protected]
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Traceability Maintenance in δ13C (CO2) Analysis: applications to continuous measurements via Picarro G1101-i Analyzer
Lin Huang, A. Chivulescu, F. Vogel, D. Ernst, D. Worthy, Y.-S. Lee, S. Racki
Climate Research Division (CRD), Atmospheric Sci. & Tech. Directorate (ASTD), STB, Environment Canada, 4905 Dufferin Street, Toronto, Ontario, M3H 5T4 Canada
A unique traceability pathway for high precision CO2 isotope measurements has been established and maintained over the last 10 years (2001-2011) in our lab. The stability of the primary anchor, which has been directly calibrated by NBS19-CO2 and used to link all the individual measurements to the primary scale of VPDB, is shown in the Figure. Taking into account of the uncertainty of the primary anchor, an overall uncertainty of individual measurements in δ13C can be estimated.
-2.70
-2.65
-2.60
-2.55
-2.50
δ13C
VP
DB
CO
2(‰
)
2012201120102009200820072006200520042003200220012000
Decimal Year
Cal2: the primary anchor on the VPDB-CO2 scale Mean: -2.600 ± 0.014 ‰
Figure 1. Stability of the primary anchor (i.e., the pure CO2 evolving from a calcium carbonate powder called “Cal2”) of δ13C on VPDB-CO2 scale during a period of 10 years (2001 to 2011) by the CRD’s stable isotope lab, Environment Canada, in Toronto. The same principle has been applied to the continuous δ13C measurements via CRDS (i.e., G1101- i Picarro 13C analyzer, the first generation). Similar to the traditional mass spectrometry measurement, an approach of using frequent injections of Target Working References and Working Standards (from high-pressure air-CO2 tanks) between sample measurements has been implemented to address the short-term noises (during the period of minutes) and long-term drifts (during the period of hours) of the analyzer. The approach will be presented and discussed, including the traceability pathway, the measurements and calibration schemes. The uncertainty of the measurements will be also estimated.
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JRAS−06; an accurate multi-point stable isotope scale anchor
for atmospheric CO2?
Magnus Wendeberg, Michael Rothe, Jürgen M. Richter, and Willi A. Brand
Max-Planck-Institute for Biogeochemistry (Beutenberg Campus; Hans-Knoell-Str.
10, 07745 Jena, Germany.
With the IMECC projecta ending in September this year the time has come to decide
about the future use of the JRAS-06b scale anchor
1-5. To date the results
c from
IMECC clearly show that the JRAS scale anchor is stable; it does not suffer from any
significant scale contraction and, because it is based on well-characterized calcite
materials, it can be maintained with the required precision and accuracy. With the
latest addition of a natural air sample to the JRAS set the number of points for CO2-
in-air scale comparisons has grown to three, covering the full range from the primary
VPDB anchor to ambient CO2–in-air values. Instead of single-point inter-comparisons
it has now become possible to directly evaluate entire local scale compatibilities
relative to the international (2-anchor) VPDB scale based on the suite of JRAS scale
anchors. To evaluate the “whole” scale has turned out to be especially useful for
revealing the rather common scale contraction issues (η-effect6). It may also serve as
a way to re-calculate archived data to the JRAS-06 based VPDB scale.
We would like to thank the laboratories that have participated in the JRAS project and
thereby helped us test and improve the JRAS concept.
1. Ghosh, P., Patecki, M., Rothe, M. & Brand, W. A. Calcite-CO2 mixed into CO2-free air: a
new CO2-in-air stable isotope reference material for the VPDB scale. Rapid Communications in Mass Spectrometry 19, 1097-1119 (2005).
2. Brand, W. A. et al. How well do we know VPDB? Variability of delta C-13 and delta O-18 in CO2 generated from NBS19-calcite. Rapid Communications in Mass Spectrometry 23, 915-926 (2009).
3. Brand, W. A., Assonov, S. S. & Coplen, T. B. Correction for the O-17 interference in delta(C-13) measurements when analyzing CO2 with stable isotope mass spectrometry (IUPAC Technical Report). Pure and Applied Chemistry 82, 1719-1733 (2010).
4. Wendeberg, M., Richter, J. M., Rothe, M. & Brand, W. A. delta O-18 anchoring to VPDB: calcite digestion with O-18-adjusted ortho-phosphoric acid. Rapid Communications in Mass Spectrometry 25, 851-860 (2011).
5. Werner, R. A., Rothe, M. & Brand, W. A. Extraction of CO2 from air samples for isotopic analysis and limits to ultra high precision delta O-18 determination in CO2 gas. Rapid Communications in Mass Spectrometry 15, 2152-2167 (2001).
6. Meijer, H. A. J., Neubert, R. E. M. & Visser, G. H. Cross contamination in dual inlet isotope ratio mass spectrometers. International Journal of Mass Spectrometry 198, 45-61 (2000).
a http://imecc.ipsl.jussieu.fr/ b JRAS = Jena Reference Air Set c http://www.bgc.mpg.de/service/iso_gas_lab/pmwiki/pmwiki.php
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Advances in instrumentation for measurements of 13CO2, C18OO and CO2 in ambient air
Doug Baer,1 Feng Dong,1 Manish Gupta,1 Robert Provencal,1Tom Owano1
1Los Gatos Research, 67 East Evelyn Avenue, Suite 3, Mountain View, CA 94041 USA
Fast, precise, and accurate measurement of δ13C (13C/12C in CO2) and δ18O of carbon dioxide is desirable for a number of applications including atmospheric chemistry and carbon sequestering. Recent advances in laser absorption spectroscopy, including cavity enhanced techniques, have enabled field portable instruments which have a number of advantages over traditional, laboratory-based mass spectroscopy systems. We report on the recent developments and improvements of an analyzer, based on a patented laser absorption technique (off-axis integrated cavity output spectroscopy or Off-Axis ICOS), which measures δ13C and δ18O in CO2, CO2, and H2O (vapor). The analyzer operates at 1 Hz and can provide a precision for δ13C of 0.1‰ (1σ) and δ18O of 1‰ (1σ) with less than 6 minutes of averaging on mole fractions typically present in ambient air. Higher precision may be reported with higher mole fractions. Besides free-flow (continuous flow) operation, the instrument also can analyze discrete gas samples (via manual injection). For ambient levels of CO2 (350 ppm to 1000 ppm), the analyzer operates with a gas volume of about 120 mL (standard). With appropriate dilution, smaller sample volumes of higher mole fractions of CO2 may be analyzed. In the case of pure (100%) CO2 samples, only 100 microliters of sample is required. In addition, the instrument also reports water vapor mixing ratio to allow the possibility of determining the CO2 mole fraction and isotopic ratios without removing water vapor (sample drying) for those applications where drying is difficult. Details concerning instrument performance, operation, sample dilution procedure, and calibration will be presented.
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Novel instrumentation for measurements of 13CH4 and 12CH4 in ambient air
Doug Baer,1Feng Dong,1 Manish Gupta,1 Robert Provencal,1Tom Owano1
1Los Gatos Research, 67 East Evelyn Avenue, Suite 3, Mountain View, CA 94041 USA
Methane is a potent greenhouse gas, whose atmospheric surface mixing ratio has almost doubled compared with preindustrial values. Methane can be produced by biogenic processes, thermogenic processes or biomass, with different isotopic signatures. As a key molecule involved in atmospheric radiative forcing, methane is thus one of the most important molecules linking the biosphere and atmosphere. Therefore precise measurements of mixing ratios and isotopic compositions will help scientists to better understand methane sources and sinks. To date, high precision isotope measurements have been exclusively performed with conventional isotope ratio mass spectrometry, which involves intensive labor and is not field deployable. Optical studies using infrared laser spectroscopy have only recently begun to report isotopic carbon ratios in methane at mixing ratios near ambient levels without preconcentration.
We present characterization of a portable Methane Carbon Isotope Analyzer (MCIA), based on cavity enhanced laser absorption spectroscopy, that provides in-situ measurements of the carbon isotope ratio (13C/12C, δ13C) and methane mole fraction (CH4) in ambient air. The gas sample is introduced to the analyzer directly without any requirement for pretreatment or preconcentration. A precision better than 1 per mill (< 1 ‰) may be achieved in less than 100 seconds (measurement time) in a 1.5-ppm methane sample (or greater) in air. Higher precision may be obtained with longer averaging and with higher mole fractions. The MCIA can report carbon isotope ratio and mole fraction measurements over a range of mole fractions ranging from 1.5 - 100 ppm CH4 in air. A dynamic dilution system, automatically controlled by the MCIA, may be used to extend the